Poison Exon Splicing Regulates a Coordinated Network of SR Protein Expression during Differentiation and Tumorigenesis

Leclair, Nathan K.; Brugiolo, Mattia; Urbanski, Laura M.; Lawson, Shane C.; Thakar, Ketan; Yurieva, Marina; George, Joshy; Hinson, J. Travis; Cheng, Albert W.; Graveley, Brenton R.; Anczuków, Olga

doi:10.1016/j.molcel.2020.10.019

Cited by 79 publications

(89 citation statements)

References 123 publications

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“…This is likely due to many factors: (i) although most SFs are expressed ubiquitously, with the notable exception of most neuronal SFs, they do exhibit tissue‐specificity in their targets. There is evidence for tissue specific regulation of gene expression and splicing (Wang, Wu, et al, 2018) and therefore SFs could display distinct functions across aged tissues; (ii) from a technical standpoint, this collection of studies utilized differing techniques to measure gene expression, used differential computational tools, and had different definitions of young and old ages; (iii) variability across studies may result from differential aging rate of tissues (i.e., Is a 60‐year old heart as “old” as a 60‐year old brain), as well as from cell composition of tissues used (i.e., some tissues are composed of more homogenous cell populations than others); (iv) many SFs themselves are alternatively spliced, often resulting in production of non‐coding transcripts, a mechanism used to regulate SF protein levels (Lareau et al, 2007; Lareau & Brenner, 2015; Leclair et al, 2020). Therefore, while the transcript level could be unchanged or changing, this might not fully reflect the final protein levels.…”

Section: Age‐related Alterations In Splicing Regulatory Componentsmentioning

confidence: 99%

Splicing alterations in healthy aging and disease

Angarola

Anczuków

2021

WIREs RNA

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Alternative RNA splicing is a key step in gene expression that allows generation of numerous messenger RNA transcripts encoding proteins of varied functions from the same gene. It is thus a rich source of proteomic and functional diversity. Alterations in alternative RNA splicing are observed both during healthy aging and in a number of human diseases, several of which display premature aging phenotypes or increased incidence with age. Age‐associated splicing alterations include differential splicing of genes associated with hallmarks of aging, as well as changes in the levels of core spliceosomal genes and regulatory splicing factors. Here, we review the current known links between alternative RNA splicing, its regulators, healthy biological aging, and diseases associated with aging or aging‐like phenotypes. This article is categorized under: RNA in Disease and Development > RNA in Disease RNA Processing > Splicing Regulation/Alternative Splicing

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Section: Age‐related Alterations In Splicing Regulatory Componentsmentioning

confidence: 99%

Splicing alterations in healthy aging and disease

Angarola

Anczuków

2021

WIREs RNA

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“…As an example of this phenomenon, we observed that exogenous expression of the truncated splicing factor SRSF3-TR causes a significant increase in the level of the corresponding aberrant SRSF3 RNA. Splicing factors are known to regulate and coordinate their expression via various forms of autoregulation (Konigs et al, 2020; Leclair et al, 2020; Muller-McNicoll, Rossbach, Hui, & Medenbach, 2019). Overexpression of full-length SRSF3 leads to a reduction in the level of normal SRSF3 transcript while at the same time activating the production of aberrant SRSF3 RNA that gets degraded by NMD in a balancing act mechanism that prevents SRSF3 accumulation (Jumaa & Nielsen, 1997).…”

Section: Discussionmentioning

confidence: 99%

Truncated RNA-binding protein production by DUX4-induced systemic inhibition of nonsense-mediated RNA decay

Campbell

Dyle

Matheny

et al. 2021

Preprint

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DUX4 is an embryonic transcription factor whose misexpression in skeletal muscle causes facioscapulohumeral muscular dystrophy (FSHD). DUX4 dysregulates multiple pathways that could contribute to FSHD pathophysiology. However, lack of temporal data and the knowledge of which RNAs are actively translated following DUX4 expression has hindered our understanding of the cascade of events that lead to muscle cell death. Here, we interrogate the DUX4 transcriptome and translatome over time and find dysregulation of most key pathways as early as 4 hours after DUX4 induction, demonstrating the potent effect of DUX4 in disrupting muscle homeostasis. We also observe extensive transcript downregulation as well as induction, and a high concordance between mRNA abundance and translation status. Significantly, DUX4 triggers widespread production of truncated protein products derived from aberrant RNAs that are degraded in normal muscle cells. One such protein, truncated serine/arginine-rich splicing factor 3 (SRSF3-TR), is present in FSHD muscle cells and disrupts splicing autoregulation when ectopically expressed in myoblasts. Taken together, the temporal dynamics of DUX4 induction show how the pathologic presence of an embryonic transcription factor in muscle cells alters gene expression at all levels of the central dogma.

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“…[ 50 ] Interestingly, all members of the SR protein family themselves contain a highly conserved PTC, also called a poison exon, allowing them to regulate their own degradation, and hence expression levels. [ 40,55,56 ] In addition to regulating itself, SRSF3 also regulates the stability of SRSF2, SRSF5 and SRSF7 transcripts. [ 40 ]…”

Section: Introductionmentioning

confidence: 99%

“…In general, SR protein expression varies between cell types but it is often higher in undifferentiated cells and decreases as differentiation progresses. [ 56 ] In some cases, such as the cardiac and neural lineages, the differences in expression levels can be explained by enhanced inclusion of their own poison exon leading to NMD in the more differentiated cells. Thus, one challenge in deciphering the precise roles of individual SR proteins in stem cell differentiation is that they act in a cross‐regulatory network by controlling their expression through NMD via their own ultraconserved poison exon sequences.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, one challenge in deciphering the precise roles of individual SR proteins in stem cell differentiation is that they act in a cross‐regulatory network by controlling their expression through NMD via their own ultraconserved poison exon sequences. [ 56 ] Evolutionary, all prototypical SR proteins share a single ancient origin, [ 8 ] and interestingly, more distantly related SR proteins tend to positively regulate each other, while more closely related SR proteins compete by negatively regulating each other's expression. [ 56 ] An SR protein network may be particularly important for brain function as SRSF3, SRSF6, SRSF7 and SRSF9 have been implicated in neurological disorders by regulating splicing of Tau, a microtubule associated protein with multiple functions required for neuronal formation and health.…”

Section: Introductionmentioning

confidence: 99%

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Noncanonical functions of the serine‐arginine‐rich splicing factor (SR) family of proteins in development and disease

Wagner

Frye

2021

BioEssays

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Members of the serine/arginine (SR)‐rich protein family of splicing factors play versatile roles in RNA processing steps and are often essential for normal development. Dynamic changes in RNA processing and turnover allow fast cellular adaptions to a changing microenvironment and thereby closely cooperate with transcription factor networks that establish cell identity within tissues. SR proteins play fundamental roles in the processing of pre‐mRNAs by regulating constitutive and alternative splicing. More recently, SR proteins have also been implicated in other aspects of RNA metabolism such as mRNA stability, transport and translation. The‐ emerging noncanonical functions highlight the multifaceted functions of these SR proteins and identify them as important coordinators of gene expression programmes. Accordingly, most SR proteins are essential for normal cell function and their misregulation contributes to human diseases such as cancer.

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Poison Exon Splicing Regulates a Coordinated Network of SR Protein Expression during Differentiation and Tumorigenesis

Cited by 79 publications

References 123 publications

Splicing alterations in healthy aging and disease

Splicing alterations in healthy aging and disease

Truncated RNA-binding protein production by DUX4-induced systemic inhibition of nonsense-mediated RNA decay

Noncanonical functions of the serine‐arginine‐rich splicing factor (SR) family of proteins in development and disease

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